Methanococcus: Difference between revisions

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{{Curated}}
{{Biorealm Genus}}
{{Biorealm Genus}}


[[Methanogens]] overview
[[Methanogens]] overview
[[Image:methanococcus_6.gif|thumb|300px|right|''Methanocaldococcus jannaschii'' courtesy of [http://biology.berkeley.edu/EML/sem.html B. Boonyaratanakornkit & D.S. Clark, Chemical Engineering, G. Vrdoljak Electron Microscope Lab, University of California Berkeley.]]]
[[Image:methanococcus_6.gif|thumb|300px|right|''Methanocaldococcus jannaschii'' courtesy of [http://em-lab.berkeley.edu/EML/images/sem.php?PHPSESSID=6e0f61ac47c40147a470df96afec633e B. Boonyaratanakornkit & D.S. Clark, Chemical Engineering, G. Vrdoljak Electron Microscope Lab, University of California Berkeley.]]]


==Classification==
==Classification==
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==Description and Significance==
==Description and Significance==


''M. jannaschii'' was the first Archaea to have it's genome sequenced, which opened the doors for comparison between the genomes of the three domains. It was originally located from a sediment sample collected from the sea floor at the base of a "white smoker" chimney on the East Pacific Rise.
''M. jannaschii'' was the first Archaeon to have its genome sequenced, which opened the doors for comparison between the genomes of the three domains. It was originally located from a sediment sample collected from the sea floor at the base of a "white smoker" chimney on the East Pacific Rise.


''Methanocaldococcus jannaschii'' was formally in the genus ''Methanococcus'', but due to it's ability to grow in high temperatures it was re-classified. There were a few thermophilic species in ''Methanococcus'' that were reorganized, and this reorganization was supported by a low 16S rRNA sequence similarity between the thermophilics and mesophilics. The species left in ''Methanococcus'' are mesophilic and are related on the genus level by close DNA reassociation levels.
''Methanocaldococcus jannaschii'' was formally in the genus ''Methanococcus'', but due to its ability to grow in high temperatures it was re-classified. There were a few thermophilic species in ''Methanococcus'' that were reorganized, and this reorganization was supported by a low 16S rRNA sequence similarity between the thermophilics and mesophilics. The species left in ''Methanococcus'' are mesophilic and are related on the genus level by close DNA reassociation levels.


No difference is noted in the G + C content of thermophilics and mesophilics of ''Methanococcus''. However, there is a difference in the proteins. The thermophilic proteins have higher residue volume, higher residue hydrophobicity, more charged amino acids, and fewer uncharged polar residues than the mesophilic proteins.
No difference is noted in the G + C content of thermophilics and mesophilics of ''Methanococcus''. However, there is a difference in the proteins. The thermophilic proteins have higher residue volume, higher residue hydrophobicity, more charged amino acids, and fewer uncharged polar residues than the mesophilic proteins.
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''M. jannaschii'' contains a main circular chromosome consisting of 1,664,970 bp, a large extra-chromosomal element with 58,407 bp, and a small extra-chromosomal element of 16,550 bp. There were similarities found in the genome with other domains, but there were also unique sequences.
''M. jannaschii'' contains a main circular chromosome consisting of 1,664,970 bp, a large extra-chromosomal element with 58,407 bp, and a small extra-chromosomal element of 16,550 bp. There were similarities found in the genome with other domains, but there were also unique sequences.


The organism ''M. voltae'' was found to contain a system of gene transfer similar to general transduction except that the bacteriophage component (in terms of virus replication) is defective or absent. VTA (''voltae'' transfer agent) is responsible for the transfer and it's 4.4kb fragments of DNA are resistant to DNase.
The organism ''M. voltae'' was found to contain a system of gene transfer similar to general transduction except that the bacteriophage component (in terms of virus replication) is defective or absent. VTA (''voltae'' transfer agent) is responsible for the transfer and its 4.4kb fragments of DNA are resistant to DNase.


[[Image:methanococcus_1.JPG]]
[[Image:methanococcus_1.JPG]]
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==Cell Structure and Metabolism==
==Cell Structure and Metabolism==


This autotrophic organism is strictly anaerobic and gets it's energy by the reduction of CO<font size="-1"><sub>2</sub></font> with H<font size="-1"><sub>2</sub></font> to generate methane. In addition to it's anabolic pathway, it also contains several scavenging molecules that most likely play a role in importing small organic compounds such as amino acids. Although ''Methanococcus'' spp. have a nifH-like gene they cannot fix N<font size="-1"><sub>2</sub></font>, with the exception of ''M. maripaludis'' that can.
This autotrophic organism is strictly anaerobic and gets its energy by the reduction of CO<font size="-1"><sub>2</sub></font> with H<font size="-1"><sub>2</sub></font> to generate methane. In addition to its anabolic pathway, it also contains several scavenging molecules that most likely play a role in importing small organic compounds such as amino acids. Although ''Methanococcus'' spp. have a nifH-like gene they cannot fix N<font size="-1"><sub>2</sub></font>, with the exception of ''M. maripaludis'' that can.


Structurally, the species consist of having two bundles of flagella at the same cellular pole along with no cell membrane, but a thin S-layer covering the plasma membrane. They are cocci in shape, about 1.0 microns in diameter, and are Gram stain negative.
Structurally, the cell has two bundles of flagella at the same cellular pole along with no cell membrane, but a thin S-layer covering the plasma membrane. They are cocci in shape, about 1.0 microns in diameter, and are Gram stain negative.


All Archaea have lipids with links between the head group and side chains, making the lipids more resistant to heat and acidity than bacterial and eukaryotic ester-linked lipids.The glycerol headgroup with two ether-linked side-chains (instead of esters) is known as ''archaeol''.:
All Archaea have lipids with links between the head group and side chains, making the lipids more resistant to heat and acidity than bacterial and eukaryotic ester-linked lipids.The glycerol headgroup with two ether-linked side-chains (instead of esters) is known as ''archaeol''.:

Latest revision as of 03:03, 1 October 2011

This is a curated page. Report corrections to Microbewiki.

A Microbial Biorealm page on the genus Methanococcus

Methanogens overview

Classification

Higher order taxa:

Archaea; Euryarchaeota; Methanococci; Methanococcales; Methanocaldococcaceae

Species:

Methanococcus jannaschii, M. maripaludis, M. voltae PS

NCBI: Taxonomy Genome

Description and Significance

M. jannaschii was the first Archaeon to have its genome sequenced, which opened the doors for comparison between the genomes of the three domains. It was originally located from a sediment sample collected from the sea floor at the base of a "white smoker" chimney on the East Pacific Rise.

Methanocaldococcus jannaschii was formally in the genus Methanococcus, but due to its ability to grow in high temperatures it was re-classified. There were a few thermophilic species in Methanococcus that were reorganized, and this reorganization was supported by a low 16S rRNA sequence similarity between the thermophilics and mesophilics. The species left in Methanococcus are mesophilic and are related on the genus level by close DNA reassociation levels.

No difference is noted in the G + C content of thermophilics and mesophilics of Methanococcus. However, there is a difference in the proteins. The thermophilic proteins have higher residue volume, higher residue hydrophobicity, more charged amino acids, and fewer uncharged polar residues than the mesophilic proteins.

Genome Structure

M. jannaschii contains a main circular chromosome consisting of 1,664,970 bp, a large extra-chromosomal element with 58,407 bp, and a small extra-chromosomal element of 16,550 bp. There were similarities found in the genome with other domains, but there were also unique sequences.

The organism M. voltae was found to contain a system of gene transfer similar to general transduction except that the bacteriophage component (in terms of virus replication) is defective or absent. VTA (voltae transfer agent) is responsible for the transfer and its 4.4kb fragments of DNA are resistant to DNase.

Methanococcus 1.JPG Methanococcus 2.JPG Partially purified, concentrated filtrates from M. voltae PS in two different preparations. Courtesy of Eiserling et al. (1999).

The majority of genes in M. jannaschii cannot be identified with Bacterial genomes or eukaryotic sequenced data. Of the similarities, Methanocaldococcus shared the anabolic genes with Bacteria (especially those involved in energy production and nitrogen fixation) and shared more of the cellular information processing and secretion systems with Eukaryotes.

Cell Structure and Metabolism

This autotrophic organism is strictly anaerobic and gets its energy by the reduction of CO2 with H2 to generate methane. In addition to its anabolic pathway, it also contains several scavenging molecules that most likely play a role in importing small organic compounds such as amino acids. Although Methanococcus spp. have a nifH-like gene they cannot fix N2, with the exception of M. maripaludis that can.

Structurally, the cell has two bundles of flagella at the same cellular pole along with no cell membrane, but a thin S-layer covering the plasma membrane. They are cocci in shape, about 1.0 microns in diameter, and are Gram stain negative.

All Archaea have lipids with links between the head group and side chains, making the lipids more resistant to heat and acidity than bacterial and eukaryotic ester-linked lipids.The glycerol headgroup with two ether-linked side-chains (instead of esters) is known as archaeol.:

Different archaea have different derivatives of archaeol, and M. jannaschii has been found to contain almost exclusively polar archaeal derivatives including maceocyclic archaeol (see image below), an archaeal core lipid. One can see that it has an additional link at the end of its sidechains.
Images from excellent article by Sturt et al.

For more information on Intact Polar Lipids (IPLs) in Archaea, including tetraethers, check the description here.

Ecology

M. jannaschii can grow in habitats with pressure up to more than 200 atm and a temperature range between 48 and 94oC, with an optimum growth temperature being 85oC.

References

Bult et al. 1996. Complete Genome Sequence of the Methanogenic Archaeon, Methanococcus jannaschii. Science 273: 1058-1072.

Eiserling et al. 1999. Bacteriophage-like particles associated with the gene transfer agent of Methanococcus voltae PS. Journal of General Virology 80: 3305-3308.

Haney et al. 1999. Thermal adaptation analyzed by comparison of protein sequences from mesophilic and extremely thermophilic Methanococcus species. PNAS 96: 3578-3583.

Sturt, Helen F.; Roger E. Summons, Kristin Smith, Marcus Elvert, and Kai-Uwe Hinrichs. "Intact polar membrane lipids in prokaryotes and sediments deciphered by high-performance liquid chromatography/electrospray ionization multistage mass spectrometry—new biomarkers for biogeochemistry and microbial ecology." Rapid Commun. Mass Spectrom. 2004; 18: 617–628.